Vacuum Tube amplifier

1. Group IV Stephen Nichols Jason Lambert Rafael Enriquez Vacuum Tube amplifier

2. Stephen A Vacuum tube audio amplifier for which the entire signal path is analog but the audio parameters are digitally controlled via a digital touch interface which controls a graphical user interface and also displays visualizations of the amplitude, frequency and phase characteristics of the audio signals. description

3. Stephen • Our project will be embody the analog aspects of modern commercial VTAs such as this one. • The unique feature of our project is digital controlled source switching, volume, and graphic equalizer with a digital touch interface and an LCD to display music visualizations. • As far as we can determine, no other modern VTA has this feature. motivation JE-Audio, model VM60 This unit is about 5” x 13” x 16” weighs about 45 pounds and costs about $6300 per pair. Image reprinted with permission from John Lam of JE-Audio

4. Jason goals CONTROL PANEL POSSIBLE MUSIC VISUALIZATIONS

5. Stephen Hardware requirements

6. Stephen INTERNAL DETAIL (TOP VIEW) Fuse Fan IO Jacks AC Power Terminal Strip High Voltage Power Supply Filament Power Supply Filament Transformer High Voltage Transformer Low Voltage Transformer Left Audio Processor Right Audio Processor Microcontroller, Low Voltage Power Supply, Optocouplers LCD Power Switch Digital Touch Panel

7. Stephen Overall BLOCK DIAGRAM SOURCES LOCAL VOLT REG B SPEAKER TO ALL AUDIO STAGES PHONO RIAA EQU INPUT SOURCESELECT GRAPHIC EQUAL-IZER TUBE PREAMP AND PHASE SPLITTER TUBE PUSH- PULL AMP Z- MATCH XFMR TAPE PRE-EQU GAIN ADJ BUFF BUFF VOL ADJ INPUTS TUNER AUX GAIN SEL IN BUFFER HIGH VOLT SUPPLY A VR1 VR2 VR3 VR4 DIGITAL POTENTIOMETERS VR5 FILAMENT SUPPLY A A B VR6 TO ALL TUBES VR7 110 VOLTS AC VR8 MICROCONTROLLER OPTO COUPLERS LOW VOLT SUPPLY 16 MILLION COLOR 800 x 480LIQUID CRYSTALDISPLAY CLOCK OSC TOUCHSCREEN EXTERNAL USB PROGRAM INTERFACE AUDIO PATH FOR ONE CHANNEL SHOWN ONLY – THE OTHER IS SIMILAR

8. Stephen AUDIO INPUT BLOCK DIAGRAM SOURCES LOCAL VOLT REG B SPEAKER TO ALL AUDIO STAGES PHONO RIAA EQU INPUT SOURCESELECT GRAPHIC EQUAL-IZER TUBE PREAMP AND PHASE SPLITTER TUBE PUSH- PULL AMP Z- MATCH XFMR TAPE PRE-EQU GAIN ADJ BUFF BUFF VOL ADJ INPUTS TUNER AUX GAIN SEL IN BUFFER HIGH VOLT SUPPLY A VR1 VR2 VR3 VR4 DIGITAL POTENTIOMETERS VR5 FILAMENT SUPPLY A A B VR6 TO ALL TUBES VR7 110 VOLTS AC VR8 MICROCONTROLLER OPTO COUPLERS LOW VOLT SUPPLY 16 MILLION COLOR 800 x 480LIQUID CRYSTALDISPLAY CLOCK OSC TOUCHSCREEN EXTERNAL USB PROGRAM INTERFACE AUDIO PATH FOR ONE CHANNEL SHOWN ONLY – THE OTHER IS SIMILAR

9. Stephen The analog multiplexer, driven by two GPIOs from the MCU, selects one of four input sources. The output of the multiplexer is buffered by a unity-gain stage to provide a constant-impedance drive for the equalizer stage. One VR channel is used to equalize the levels of the various signals (see chart) and is set to a pre-determined value by the MCU as the sources are selected. AUDIO INPUT PROCESSING

10. Stephen AUDIO INPUT SCHEMATIC From low-voltage power supply To graphic equalizer From back panel input jacks (not shown) From MCU

11. Stephen • Op-amps: • The Texas Instruments’ LM4562 • Analog Multiplexer: • The Analog Devices’ ADG408 AUDIO INPUT DESIGN DECISIONS The ADG408BN was chosen due to excellent crosstalk, compatibility with the power supply voltages and performance during simulation

12. Jason GRAPHIC EQUALIZER SOURCES LOCAL VOLT REG B SPEAKER TO ALL AUDIO STAGES PHONO RIAA EQU INPUT SOURCESELECT GRAPHIC EQUAL-IZER TUBE PREAMP AND PHASE SPLITTER TUBE PUSH- PULL AMP Z- MATCH XFMR TAPE PRE-EQU GAIN ADJ BUFF BUFF VOL ADJ INPUTS TUNER AUX GAIN SEL IN BUFFER HIGH VOLT SUPPLY A VR1 VR2 VR3 VR4 DIGITAL POTENTIOMETERS VR5 FILAMENT SUPPLY A A B VR6 TO ALL TUBES VR7 110 VOLTS AC VR8 MICROCONTROLLER OPTO COUPLERS LOW VOLT SUPPLY 16 MILLION COLOR 800 x 480LIQUID CRYSTALDISPLAY CLOCK OSC TOUCHSCREEN EXTERNAL USB PROGRAM INTERFACE AUDIO PATH FOR ONE CHANNEL SHOWN ONLY – THE OTHER IS SIMILAR

13. Jason Graphic equalizer • DESIGN DECISIONS

14. Jason GRAPHIC EQUALIZER

15. Boost graphs are shown; cut graphs are mirror-image GRAPHIC EQUALIZER SIMULATION 1000 Hz 30 Hz 100 Hz 3000 Hz 300 Hz 10000 Hz

16. Jason GRAPHIC EQUALIZER

17. Jason Digital Potentiometers • DESIGN DECISIONs

18. Jason Digital potentiometers • difficulties • The AD8403 is extremely sensitive to ESD and improper voltages. We had numerous mishaps that rendered the chips useless. • As resolution we are following ESD precautions and double checking connections before applying power.

19. Stephen VTA BLOCK DIAGRAM SOURCES LOCAL VOLT REG B SPEAKER TO ALL AUDIO STAGES PHONO RIAA EQU INPUT SOURCESELECT GRAPHIC EQUAL-IZER TUBE PREAMP AND PHASE SPLITTER TUBE PUSH- PULL AMP Z- MATCH XFMR TAPE PRE-EQU GAIN ADJ BUFF BUFF VOL ADJ INPUTS TUNER AUX GAIN SEL IN BUFFER HIGH VOLT SUPPLY A VR1 VR2 VR3 VR4 DIGITAL POTENTIOMETERS VR5 FILAMENT SUPPLY A A B VR6 TO ALL TUBES VR7 110 VOLTS AC VR8 MICROCONTROLLER OPTO COUPLERS LOW VOLT SUPPLY 16 MILLION COLOR 800 x 480LIQUID CRYSTALDISPLAY CLOCK OSC TOUCHSCREEN EXTERNAL USB PROGRAM INTERFACE AUDIO PATH FOR ONE CHANNEL SHOWN ONLY – THE OTHER IS SIMILAR

20. Stephen VTA SCHEMATIC From graphic equalizer To speaker 5.75 Volts DC for tube heaters From High Voltage Power Supply 420V @ 120mA

21. Stephen Four candidate architectures were investigated early in the project to select the design approach of the power amplifier. Design 1 was chosen as offering the best frequency response and highest power at the lowest distortion. VTA ARCHITECTURE selection

22. Stephen VTAs are favored by many musicians and high-end audio enthusiasts for their mellower sound and low-distortion characteristics. This effect, known as “tube sound”, is believed to come from the “soft clipping” characteristics of vacuum tube amplifiers which emphasize even-order harmonics, as opposed to solid-state designs that tend to produce odd-order harmonics when they sharply clip during musical peaks. During the architecture selection, the distortion characteristics of the various configurations were analyzed with NI Multisim. In general, the even-order harmonics tended to be of higher amplitude than the next odd-order harmonic (see Table1). Note that even-order harmonics are simply the same musical note at a higher octave (see Table 2) VTA DISTORTION Table 1 Table 2 (Music notes are per the Equal Tempered Chromatic Scale)

23. Stephen V3 is a dual-triode tube configured as a phase splitter. Various reference designs used type 12xx7 tubes so several were analyzed in NI Multisim. The type 12BH7A was chosen due to slightly lower THD characteristics V2 and V1 are beam power pentode tubes configured as a push-pull amplifier with a center-tapped transformer as their plate load. Type 6L6 tubes were chosen due to almost universal use in reference designs. Impedance Transformer: The model 125E was chosen due to being specifically designed for this application, flexible impedance ratio and availability. It provides six taps on the secondary ranging from 3KΩ to 22.5KΩ. A value of 5.6KΩ ohms was chosen because it provided the best combination of maximum output power and THD. VTA DESIGN decisions

24. Stephen • The optimal configuration of the push-pull amplifier was challenging due to several conflicting factors: • Maximum output power occurs with the highest plate voltage. High plate voltages unfortunately run the risk of exceeding the 6L6 maximum plate voltage rating of 500 volts. • Lowest distortion was achieved with lower values of cathode resistor, however this resulted in higher plate voltages. Audio processor difficulties

25. Stephen The entire audio processor circuit worked very well when prototyped. A few minor schematic issues were discovered during this process, which have been resolved. Audio processor successes

26. Stephen HV POWER SUPPLY BLOCK DIAGRAM SOURCES LOCAL VOLT REG B SPEAKER TO ALL AUDIO STAGES PHONO RIAA EQU INPUT SOURCESELECT GRAPHIC EQUAL-IZER TUBE PREAMP AND PHASE SPLITTER TUBE PUSH- PULL AMP Z- MATCH XFMR TAPE PRE-EQU GAIN ADJ BUFF BUFF VOL ADJ INPUTS TUNER AUX GAIN SEL IN BUFFER HIGH VOLT SUPPLY A VR1 VR2 VR3 VR4 DIGITAL POTENTIOMETERS VR5 FILAMENT SUPPLY A A B VR6 TO ALL TUBES VR7 110 VOLTS AC VR8 MICROCONTROLLER OPTO COUPLERS LOW VOLT SUPPLY 16 MILLION COLOR 800 x 480LIQUID CRYSTALDISPLAY CLOCK OSC TOUCHSCREEN EXTERNAL USB PROGRAM INTERFACE AUDIO PATH FOR ONE CHANNEL SHOWN ONLY – THE OTHER IS SIMILAR

27. Stephen TUBE POWER SUPPLIES HIGH VOLTAGE FOR TUBE PLATE CIRCUITS “B+” Nominal 420 Volts DC to the VTA 360 Volts AC HIGH CURRENT FOR TUBE FILAMENTS

28. Rafa Low voltage power supply

29. Rafa Low voltage power supply

30. Rafa • Incorrect display documentation caused an incorrect initial design. • The schematic for the panel and the physical panel had discrepancies • Incorrect labeling of the panel caused a malfunction of the DC to DC converters Low voltage power supply Difficulties

31. Jason Microcontroller topology • Design decisions

32. Jason Microcontroller selection • Design decisions

33. Rafa display requirements

34. Rafa display options

35. Rafa display decision

36. Rafa display difficulties

37. Rafa display successes

38. State Detector Sound Analyzer Values Updater Graphics Generator I Graphics Generator II Graphics Update Rafa Display Software diagram • Visualization EQ

39. Stephen This project is self-funded by the group, with Stephen providing 90% of the funds The original budget of this project was $500 As of now, approximately $700 has been spent OVERALL Budget & financing details

40. questions